Control of Petersen Coils Gernot Druml, Member, IEEE , Andreas Kugi , Member, IEEE , Bodo Parr
--In Abstract --In
this paper we present a new method for the control of Petersen coils in resonant grounded networks. The major problem for the tuning at small neutral-to-earth voltages is to distinguish between resonance points simulated by the disturbances and real resonance points. In addition the controller has to recognize network modifications during the tuning operation. The first part of this contribution is a short description of the essential parameters that define the resonance curve. The second part deals with the disturbances at very small neutral-to-earth voltages. In consideration of these disturbances a new algorithm is presented to improve the accuracy of the tuning operation of the Petersen coil.
Index Terms -- Petersen coil, resonant grounding, transmission lines.
I. I NTRODUCTION NTRODUCTION
T
HE “resonant
grounding” is one of the most important options in electrical network design to obtain the optimal power supply quality. The main advantage of the treatment of the neutral point is the possibility of continuing the network operation during a sustained earth-fault. As a consequence this reduces the number of interruptions of the power supply for the customer. customer. For the suppression of the arc the Petersen coil should be well tuned within limits, which are described in [1] and [9] for the different insulation levels. The increase in the cable lengths of distribution networks brings about that on the one hand the level of the neutral-to-earth voltage is decreasing and on the other hand the resonance curves become sharper. The reason for the reduction of the neutral-to-earth voltage level is mainly due to the reduced capacitance tolerances of the new cables. Furthermore, the cables have smaller losses compared to equivalent overhead lines. This is why, the damping of the network is reduced and the resonance curves become sharper. A first idea to meet these new demands on the control of Petersen coils is to make the measurement of the neutral-toearth voltage more sensitive. But in this paper we will show that with this idea we do not get satisfactory results. The main reason for this is that the disturbances caused by the system due to, e.g. geometrically asymmetric installed cables, are higher than the measurement noise. Therefore, we will direct our attention to elaborate the reasons for the
different disturbances of the neutral-to-earth voltage. Finally, a new approach for finding the resonance point also for smaller neutral-to-earth voltage levels will be presented.
II. BASICS OF THE R ESONANT ESONANT GROUNDING A. Principals of the resonant grounding In medium-voltage (MV) and high-voltage (HV) networks with “resonant grounding” the current over the fault location in the case of a single line-to-earth-fault (SLE) is reduced by the use of the Petersen coil. For this the Petersen coil is adjusted during the sound operation of the network to compensate the capacitive current over the fault location by an inductive current. Fig. 1 shows the simplified equivalent circuit used for a faulty distribution system where we assume ideal symmetrical three-phase voltage sources and negligible line resistances and inductances. V 3 E 3 I 3 E 2 I 2
N V ne
V 2 V 1
E 1 I 1
G P
I F
L P
C 1
C 2
C 3
Z F =0 Earth
I C 2 I p
Fig. 1.
I C 3
Simplified equivalent circuit for the “resonant grounding”.
The phasor diagram of fig. 1 for a SLE with Z F = 0 Ω is depicted in fig. 2a. The situation of different coil positions of the Petersen coil and the resulting current I F over the fault location are shown in fig. 2b. 2
3
V 21
V ne
I Lp I Gp
1 I C 2 + I C 3
I P Earth
I C 3
V en
V 31
I C2
I F
I Gp
I C 2 +I C 3 I Lp
overcompensation
undercompensation
full-compensation
Gernot Druml is working with a-eberle gmbh in Nuremberg, Germany (e-mail: g.druml@ ieee.org). Andreas Kugi is with the Department of Automatic Control and Control Systems Technology Technology of the Johannes Kepler University in Linz, Austria (email:
[email protected]). Bodo Parr is working in the research group of a-eberle gmbh in Nuremberg, Germany Germany (e-mail:
[email protected]).
[email protected]).
XI. International Symposium on Theoretical Electrical Engineering August / 2001
a) Fig. 2. 2.
b)
a) Phasor Phasor diagram for a single line-to-earth-fault (SLE). b) Reduced phasor diagram.
Page 1 / 7
L P , G P C 1, C 2, C 3 Z F N
Y 1 + a 2Y 2
+ aY 3 = ∆G + jω∆C Y 1 + Y 2 + Y 3 = (3G + ∆G ) + jω (3C + ∆C )
Petersen coil (inductance, conductance) line-to-earth capacitances impedance at the fault location star point of the transformer (neutral point) phase voltages neutral-to-earth voltage capacitive current of the two sound lines current of the Petersen coil wattmetric part of I P inductive part of I P current over the fault location
E 1, E 2, E 3 V ne I C2 , I C3 I P I GP I LP I F
and hence eq. (11) results in Y U V ne = − E 1 Y U + Y W + j ( BC − B L ) with Y U = ∆G + jω∆C
= 3G + G P BC = ω 3C
For the derivation of the mathematical model the following assumptions will be made (see fig. 3): Ø The line-to-earth capacitances and conductances are symmetrical and Ø the line-unbalance (capacitive and ohmic) is reduced to phase 1. V 3
N
V ne G P
E 3
I 3
E 2
I 2
E 1
I 1
inductive part of Y O .
ω L P
The equivalent circuit of eq. (14) is depicted in fig. 4. This circuit is valid for low ohmic single line-to-earth-faults as well as for the natural capacitive unbalance of the sound network provided that the previous assumptions are satisfied.
E 1
I F G
G C
C
Y U + Y O
(14)
E 1
capacitive part of Y O
Yu
V 1
Y U
wattmetric part of Y O
1
V 2
L P G
=
(13)
unbalance of the fault location
Y W
B L
=−
(12)
I F
V en = - V ne
Y W
B C
BL
G C
C
Earth
Fig. 4. Single phase equivalent circuit for the “resonant grounding”. I C 2
I Lp
In the following subsections the dependence of V ne and I F on the tuning of the Petersen coil under the two major operation conditions will be discussed.
I C 3
Fig. 3. Simplified equivalent circuit.
B. Low ohmic single line-to-earth-fault: For the equivalent circuit of fig. 3 the following equations 0 = I P + I 1 + I 2 + I 3 V neY P = I P
In the case of a low ohmic earth-fault the capacitive (1) unbalance jBC is negligible. On the other hand the ohmic (2) admittance ∆G is very high. As a result of these conditions
( E 1 + V ne )Y 1 = I 1
(3) the voltage on the resonance circuit V ne is more or less (4) constant (see also fig. 4). Fig. 5 shows the absolute value
+ V ne )Y 2 = I 2 ( E 3 + V ne )Y 3 = I 3
( E 2
(5)
Hold, with the admittances 1 Y P = G P + jω L P
(6)
and fig. 6 the locus diagram of the current I F over the fault location as a function of the Petersen coil position I pos = B L E 1 for a typical 20 kV network ( BC E 1 = 150 A, Y W E 1 = 5 A and 1/Y U = 1 ). Ω
(7)
= (G + ∆G ) + jω (C + ∆C ) Y 2 = Y 3 = G + jωC . Y 1
(8)
Assuming a symmetrical three-phase system and using the abbreviation a = e − j120° with 0 = 1 + a + a 2 , we can write the voltages E 2 and E 3 in the form
E 2
= a 2 E 1
and E 3
= aE 1 .
(9)
Now eq. (1) yields to
0 = V ne (Y P + Y 1 + Y 2 + Y 3 ) + E 1 (Y 1 + a 2Y 2
+ aY 3 )
(10)
or equivalently V ne
= −
Y 1 + a 2Y 2
+ aY 3 E 1 . Y P + Y 1 + Y 2 + Y 3
(11)
Using eqs. (6) - (8), we get Fig. 5. Absolute value of the current over the fault location I F .
XI. International Symposium on Theoretical Electrical Engineering August / 2001
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Fig. 6. Locus diagram of the current over the fault location I F . Fig. 8. Locus diagram of the neutral-to-earth voltage V ne.
C. Natural capacitive unbalance of the sound network In this case the ohmic admittance ∆G is normally negligible compared to the capacitive unbalance jBC of the network. As a consequence the current I F is more or less constant (see fig. 4). In analogy to the previous subsection fig. 7 shows the absolute value and fig. 8 the locus diagram of the neutral-to-earth voltage V ne at the fault (unbalance) location as a function of the Petersen coil position I pos = B L E 1 for a typical 20 kV network ( BC E 1 = 150 A, Y W E 1 = 5 A and 1/Y U = 40 k Ω ).
V res
= −
Y U Y U + Y W
(15)
E 1 .
In order to explain the meaning of the current I w, let us consider the point of the resonance curve from fig. 7 or fig. 8 V ne
where the relation
V res
=
1 2
holds. Thus, under the
assumption Y U << Y W the corresponding coil position I pos,W = B L,W E 1 can be calculated from eq. (14) in the form (16)
V ne V res
=
1 2
1
= 1+
j ( BC − B L,W ) Y U + Y W
1
≈ 1+
j ( BC − B L ,W ) Y W
or equivalently ( BC − B L ,W ) = Y W .
(17)
Multiplying eq. (17) with E 1, we get the relations ( BC − B L ,W ) E 1 = I res − I pos ,W = Y W E 1 = I W .
(18)
Thus, eq. (18) says that the difference between the coil position at the resonance point I res and the coil position I pos,W where the voltage V ne is reduced to V res / 2 is equal to the wattmetric current I W. Fig. 7. Absolute value of the neutral-to-earth voltage V ne.
The resonance curve of the sound network can be described by the following three parameters: V res I res I w
For the explanation of the new control algorithm it will be useful to consider the absolute value and the locus diagram of the inverse of the neutral-to-earth voltage Y U + Y W + j ( BC − B L ) 1 (19)
= −
maximum voltage of the resonance curve V ne Y U E 1 corresponding coil position to V res as presented in the figs. 9 and 10. wattmetric current over the fault location in the case of a low ohmic earth-fault III. DISTURBANCES OF THE CONTROL OPERATION These parameters can be determined from the resonance Following the previous discussion it seems to be very easy to curve in an easy way. At the resonance point ( BC = B L) eq. find the resonance point of the sound network even for very (14) simplifies to small neutral-to-earth voltages. The problem becomes more difficult because several disturbances generate a non-zero
XI. International Symposium on Theoretical Electrical Engineering August / 2001
Page 3 / 7
7.
8.
9.
10.
Fig. 9. Absolute value of the neutral-to-earth voltage 1/V ne.
11.
12.
13.
Fig. 10. Locus diagram of the neutral-to-earth voltage 1/V ne.
neutral-to-earth voltage V ne. Thus, it is very difficult for the control algorithm to distinguish between “real” resonance points and “fictitious” resonance points caused by the disturbances. Next we will discuss the different reasons for the disturbances of the measurement of V ne : 1. High noise levels in the measurement of V ne due to, e.g. inductive and capacitive coupling on the line from the measurement winding of the Petersen coil to the controller. This effect can be reduced, by using twisted and shielded measurement lines. 2. Resolution of the A/D converter. The resonance maximum in cable networks is often less than 0.5 % of E 1. Thus, in order to identify a resonance curve the resolution should be in the range of 0.01 % of E 1. 3. Harmonics in the zero-sequence system. They can be filtered in the controller. 4. Unbalance of the voltage (dE 1) coupled from the HV. 5. Unbalance of the voltage (dE 1) due to manufacturing tolerances of the transformer in the range less than 1 %. As a result a completely balanced HV-system generates an unbalanced system on the MV side. 6. An asymmetric load of the auxiliary system on the tertiary winding of the earthing-transformer (zig-zag) also generates an unbalance of the voltage ( dE 1).
XI. International Symposium on Theoretical Electrical Engineering August / 2001
Capacitive unbalance of the lines due to, e.g. the geometrical arrangement of the phases in overhead lines or due to the manufacturing tolerances of cables. Coupling of the load current over the normally negligible line resistances and reactances (symmetric and asymmetric values). Coupling of the load current over the normally negligible mutual coupled line reactances (symmetric and asymmetric values). Measurement of the neutral-to-earth voltage V ne using the open delta winding at the busbar instead of the auxiliary winding of the Petersen coil results in a constant amplitude and phase error. This is caused by the different accuracy classes of the open delta winding and the transformer. Non-linearity between the measured coil position and the real susceptance of the Petersen coil. The sensor for the coil position is a linear potentiometer, which gives a signal proportional to the air gap. But the susceptance of the Petersen coil is a non-linear function of the air gap. Capacitive coupling from parallel lines of different voltage levels on the same lattice tower. To reduce the required ground floor, lines with different voltage levels are installed on the same lattice tower. Due to this, changes in the balance of one system are capacitively coupled to the second system. Combination of the disturbances mentioned above where unbalanced loads are important.
In order to get an impression of the quantitative influence of some of these disturbances on the neutral-to-earth voltage V ne, in particular 4 to 9, we will subsequently investigate a simple 20 kV network. A. Description of the network The network under consideration consisting of a transformer, the Petersen coil, a transmission line and a load is depicted in fig. 11. Transformer
N
V ne
Line
E 3
Z L 3
E 2
Z L 2
E 1
Z L 1 Z M 12
Z M 23
Z M 13
Load V 3
Z Load 3
V 2
Z Load 2
V 1
Z Load 1
N 2
dE 1
Y P I P Earth
Y 1
Y 2
Y 3
I 1
I 2
I 3
Fig. 11. Simple equivalent circuit for the investigation of some disturbances on the neutral-to-earth voltage V ne.
Let us assume that Ø the transformer (110 kV / 20 kV) is ideal with no losses and no leakage inductance, Ø the line is 44.5 km long with z M 12, M 23, M 13 = j 0.01665
Ω/km, y1, 2,3 = j9.4251×10 −5 1/(Ω km) and z L1, L2, L3 = (0.233 + j0.1665) Ω/km,
Page 4 / 7
Ø
the admittance of the Petersen coil has the value Y P = (0.432 + j 12.987) 1/Ω and
Ø
the load is within the range Z Load 1, Load 2, Load 3 = 38.5 -
`
Ω. For the sake of clarity, we further assume without restriction of generality that unbalances of the transmission line only occur in phase 1. Furthermore, the mutual coupling of the transmission lines is neglected because if the network is symmetrical it only has minor influence on the results. The case of asymmetrical mutual coupling can be treated in a similar way as an unbalance in the series reactance of one phase. It is worth mentioning that the equations for a complete description of the different coupling effects of networks with asymmetrical components are very complex and cannot be simplified by using the classical symmetrical component concept (see, e.g. [3] [6] [11]). The disturbances described in the items 4 to 9 can be reduced to the following three coupling effects, which will be discussed in more detail on the basis of the network of fig. 11: Ø Unbalance of the voltage ( dE 1). Ø Unbalance of the line-to-earth capacitances. Ø Coupling of the load current over the normally negligible line resistances and reactances.
1) Unbalance of the voltage dE 1 Under the assumption that all components of the network are symmetrical except for the unbalanced voltage dE 1 we get the following relation between V ne and dE 1
dE 1
= −
Y LY C 3Y LY C + Y P (Y L
2) Unbalance of the line-to-earth capacitances For this investigation we assume that dE 1 = 0 and that there is only an unbalance ∆Y C in the line-to-earth capacitance in phase 1. Then the following relation V ne E 1 V ne E 1
B. Coupling phenomena for V ne
V ne
Fig. 12. Neutral-to-earth voltage due to an unbalance on the HV side.
= −
∆Y C 3Y n1 + Y n 2
= −
∆Y C 3Y n1 + Y n 2 3Y L
2
2
(21)
can be found with
= (Y C + Y L + Y Load + ∆Y C )(3Y L Y C + Y P (Y L + Y C )) 2 Y n 2 = ∆Y C (3Y L + Y Load (Y P + 3Y L )) Y n1
(20) Y Load
+ Y C )
3Y L
=
(22)
1 Z Load
∆Y C = jω∆C .
with Y L
=
1
series line admittance
( R L + jω L L )
Y C = jωC Y P = G P +
line-to-earth capacitive admittance 1 jω L P
admittance of the Petersen coil.
The important information of eq. (20) is that even in a network with ideal symmetrical components (line resistances, line reactances, mutual coupling, line-to-earth capacitances and loads) an unbalance dE 1 will produce a non-zero neutral-to-earth voltage V ne. In addition, the amplitude of this voltage depends on different network parameters and has its maximum in the case when the Petersen coil is adjusted. The relation
V ne / dE 1 as a
function of the coil position for the network of fig. 11 is shown in fig. 12.
XI. International Symposium on Theoretical Electrical Engineering August / 2001
The natural unbalance in the line-to-earth capacitance ∆Y C also brings about a non-zero neutral-to-earth voltage V ne. But now V ne also depends on the load Y Load and hence on the load current due to the serial impedance of the line. As it can be seen from eq. (21) and eq. (22) this dependence is even present if both the serial line impedance and the load are symmetrical. If there are additional asymmetries in the serial impedances, e.g. due to asymmetrical mutual coupling of the overhead lines, the coupling effect can be worse. Fig. 13 depicts the relation V ne / E 1 as a function of the load current in the case of an adjusted Petersen coil for the network of fig. 11. 3) Unbalance of the serial impedances of the line For this calculation the assumption dE 1 = 0 and a symmetrical network except for an asymmetry of 5% in Z L of phase 1 is made. The mathematical relations for this case are systematically derived by means of a special package written in the computer algebra program MAPLEV (see [7]). Since the formulas are rather complex we restrict ourselves to
Page 5 / 7
present the graph of the relation V ne / E 1 in fig. 14 as a function of the load current in the case of an adjusted Petersen coil for the network of fig. 11.
2
Z M 13
1
Z M 12
2
Z M 23
Z M 12
3
1
2 r a
Z M 23
3 Z M 13
a
a
a)
b)
Fig. 15. a) Single conductor cables in parallel. b) Single conductor cables in triangle.
IV. CONTROL OF THE PETERSEN COIL The only quantities being measurable for the controller are the actual coil position and the neutral-to-earth voltage V ne. Fig. 16 depicts the controller interface of the Petersen coil.
Controller Fig. 13. Neutral-to-earth voltage due to a capacitive unbalance and nonzero serial impedances in the line.
Petersen-Coil L
R 1
motor high
R 2
motor low N +U H
E 1
endswitch high
E 2
endswitch low -U H + Pot s Pot
I pos
P ot
V en
V en
coil-position ( air-gap )
V en = 0...100VAC
Fig. 16. Controller interface of the Petersen coil.
Fig. 14. Neutral-to-earth voltage due to an unbalance of the serial impedances in the line.
The important result is that there is an increasing neutralto-earth voltage V ne depending on the load current. If the load current is zero V ne results from the capacitive current of the line itself. In some networks the neutral-to-earth voltage is zero in the case of no-load operation of the network. The coupled voltages of the capacitive unbalance and of the unbalance of the serial impedances are compensating themselves. But as it can be seen in fig. 14 the neutral-toearth voltage V ne is increasing depending on the load. The asymmetry of a line may be caused for example by the kind of laying the cables, as shown in figure 15a (for further details the reader is referred to [4][10][11]). If the cables are laid in a triangle (see Fig. 15b) the mutual coupling of the three phases is obviously the same. A similar situation can be found for overhead lines where an improvement can be made, by transposing the phases.
XI. International Symposium on Theoretical Electrical Engineering August / 2001
The task of the controller is to detect a change of the network configuration and to adjust the Petersen coil to the new resonance point or to a predefined over- or undercompensated value [12]. In the simplest version the change of the absolute value of the neutral-to-earth voltage V ne is used as an indication of a switch operation in the network. With this approach not all changes of the network configuration can be detected. An improvement can be made, by investigating the change of the neutral-to-earth voltage V ne in the complex plane [2]. To calculate the resonance curve parameters it is necessary to change the value of the Petersen coil and to measure the corresponding variation of the neutral-to-earth voltage V ne. As shown in the sections before, the voltage V ne is corrupted by different disturbances. Summarizing the objectives, the controller has Ø to distinguish between a “real” resonance point and a “fictitious” resonance point, in particular in the case of small neutral-to-earth voltages and Ø to recognize switch operations during the tuning operation of the Petersen coil. It has turned out that by means of a least-squares approach (see, e.g. [8]) the parameters V res, I res and I W of the resonance curve of fig. 7 can be obtained in a robust way. The Petersen
Page 6 / 7
coil needs in its fastest operation mode about 60 s from one end-switch to the other. This requires that during the tuning operation about every 0.5 s a new estimation is accessible. To avoid too high computational consumption the non-linear parameter estimation problem is transformed to a linear one. For this purpose let us consider eq. (19) in the form 2
V ne E 1
=
1 T
2
=
(23)
1 2
Y W 1 + Y U
2
B − B + C L Y U
or equivalently 0 = Y U
2
+ 2Y U Y W + Y W 2 + BC 2 − 2 BC B L − Y U 2
T
2
+ B L 2 .
(24)
2
Since T and B L can be measured, we can rewrite eq. (24) for n different measurement points in the form 1
− 2 B L − T ... ... ... ... − 2 B L − T 2 n 2
1
− B L 2 x ... 1 ... x = ... 2 ... x3 2 − B L 1
Fig. 18. Inverse resonance curve estimated from the sampled values.
(25)
VI. CONCLUSION
In this contribution we have discussed the principle of “resonant grounding” and the effect of different disturbances with the abbreviations on the measurements. A prerequisite for an automatic x1 = BC (26) control operation of the Petersen coil is an unbalance in the 2 (27) network in order to get a non-zero neutral-to-earth voltage. x2 = Y U 2 2 2 (28) To see the limits of this concept, we have elaborated the x3 = Y U + 2Y U Y W + Y W + BC . different disturbances, which may occur in every real-world network. According to these requirements we have presented Eq. (25) can be solved with a classical least squares a new algorithm to reduce the influence of the disturbances. approach in order to obtain BC , Y U and Y W and from this the The field test and the first practical experiences show the parameters V res, I res and I W for the construction of the effectiveness of this new concept for the control of Petersen resonance curve. It is worth mentioning that for the sake of coils. computational efficiency an on-line version of the leastsquares algorithm is implemented [8]. However, some R EFERENCES further steps in the preprocessing of the signals have to be [1] DIN VDE 0228, Maßnahmen zur Beeinflussung von taken to gain additional robustness against disturbances. Fernmeldeanlagen durch Starkstromanlagen, 1987. [2]
V. R ESULTS OF FIELD TESTS
[3] [4]
In the meantime the new algorithm is implemented in a real hardware and has shown his advantages in real network configurations. As an example fig. 17 shows the estimated inverse resonance curve (see eq. (19) and fig. 9), by using only the marked samples from the measured values for the computation of the parameters. The real resonance point of the network is at 100 A. The accuracy obtained is sufficient for the required tuning.
[5] [6]
[7]
[8] [9]
[10] [11] [12]
XI. International Symposium on Theoretical Electrical Engineering August / 2001
Druml G., Resonanzregler REG-DP, Betriebsanleitung , a-eberle gmbh Nürnberg, 2001. Grainger J., Stevenson W., Jr., Power System Analysis, McGraw-Hill, Singapore, 1994. Heinhold L., Kabel und Leitungen für Starkstrom, Siemens, BerlinMünchen, 4.Aufl., 1987. Hubensteiner H., Schutztechnik in elektrischen Netzen 1, VDE Verlag, Berlin-Offenbach, 1993. Koettnitz H., Pundt H., Berechnung elektrischer Energieversorgungs- netze, Mathematische Grundlagen und Netzparameter , VEB Deutscher Verlag für Grundstoffindustrie, Leipzig, 1973. Kugi A., Schlacher K., Kaltenbacher M., Object oriented approach for large circuits with substructures in the computer algebra program Maple V , In: Software for Electrical Engineering Analysis and Design, Ed.: Silvester P.P., pp. 490-500, Computational Mechanics Publica-tions, Southampton, 1996. Ljung L., System Identification: Theory for the User, Prentice Hall, New Jersey, 1987. Poll J., Löschung von Erdschlusslichtbögen, In: Elektrizitätswirtschaft, Jg.83 (1984), Heft 7, pp 322-327, VWEWVerlag, Frankfurt am Main VDEW: Kabelhandbuch, VWEW-Verlag, Frankfurt am Main, 1997. Weßnigk K., Kraftwerkselektrotechnik , VDE Verlag, BerlinOffenbach, 1993. Willheim R., Waters M., Neutral Grounding in High-Voltage Transmission, Elsevier Publishing Company, London, 1956.
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